The molecular physiology and pathology of fibrin structure/function

The formation of a fibrin clot is a pivotal event in atherothrombotic vascular disease and there is mounting evidence that the structure of clots is of importance in the development of disease. This review describes the crucial events in the formation and dissolution of a clot, with particular focus on genetic and environmental factors that have been identified as determinants of fibrin structure in vivo, and discusses the substantiation of the relationship between fibrin structure and disease in conjunction with a review of the current literature.     

Role of factor XIII in fibrin clot formation and effects of genetic polymorphisms

Factor XIII and fibrinogen are unusual among clotting factors in that neither is a serine protease. Fibrin is the main protein constituent of the blood clot, which is stabilized by factor XIIIa through an amide or isopeptide bond that ligates adjacent fibrin monomers. Many of the structural and functional features of factor XIII and fibrin(ogen) have been elucidated by protein and gene analysis, site-directed mutagenesis, and x-ray crystallography. However, some of the molecular aspects involved in the complex processes of insoluble fibrin formation in vivo and in vitro remain unresolved. The findings of a relationship between fibrinogen, factor XIII, and cardiovascular or other thrombotic disorders have focused much attention on these 2 proteins. Of particular interest are associations between common variations in the genes of factor XIII and altered risk profiles for thrombosis. Although there is much debate regarding these observations, the implications for our understanding of clot formation and therapeutic intervention may be of major importance. In this review, we have summarized recent findings on the structure and function of factor XIII. This is followed by a review of the effects of genetic polymorphisms on protein structure/function and their relationship to disease.     

Fibrin clot structure and function: a role in the pathophysiology of arterial and venous thromboembolic diseases

The formation of fibrin clots that are relatively resistant to lysis represents the final step in blood coagulation. We discuss the genetic and environmental regulators of fibrin structure in relation to thrombotic disease. In addition, we discuss the implications of fibrin structure for treatment of thrombosis. Fibrin clots composed of compact, highly branched networks with thin fibers are resistant to lysis. Altered fibrin structure has consistently been reported in patients with several diseases complicated by thromboembolic events, including patients with acute or prior myocardial infarction, ischemic stroke, and venous thromboembolism. Relatives of patients with myocardial infarction or venous thromboembolism display similar fibrin abnormalities. Low-dose aspirin, statins, lowering of homocysteine, better diabetes control, smoking cessation, and suppression of inflammatory response increase clot permeability and susceptibility to lysis. Growing evidence indicates that abnormal fibrin properties represent a novel risk factor for arterial and venous thrombotic events, particularly of unknown etiology in young and middle-aged patients.     

Fibrinogen and fibrin: scaffold proteins in hemostasis

PURPOSE OF REVIEW: Elevated fibrinogen is a cardiovascular risk factor. Recent work provides a rationale for this risk, as abnormal fibrin clot structure, strength and stability correlates with coronary artery disease. This review describes in-vitro experiments whose intent is to define the molecular mechanisms that control clot architecture and function in vivo. RECENT FINDINGS: Biochemical and structural data continue to define the interactions between monomer units that assemble into a fibrin clot. In particular, 'A: a' interactions dominate the first step in fiber formation, while the analogous 'B: b' interactions have a minor role. Studies show the N-terminus of Bbeta, the C-terminus of Aalpha, and the splice variant gamma' modulate fibrin clot structure. Measurement of the mechanical properties of fibrinogen and fibrin show fibrin fibers are among the strongest in nature. Studies have identified fibrinogen-binding proteins that influence clot structure and function. SUMMARY: These findings defined mechanisms that control fibrin clot structure, strength and stability. This basic information provides direction for clinical studies to examine clot properties in pathologic thrombosis and pharmaceutical studies to develop therapeutic interventions to prevent or control cardiovascular disease. These studies also establish novel techniques to examine individual bonds, molecules and fibers.     

Fibrinogen heterogeneity: inherited and noninherited

PURPOSE OF REVIEW: Many noninherited or inherited variations have been described in fibrinogen and they may affect the different functions of fibrinogen. RECENT FINDINGS: A number of the acquired variations in fibrinogen affect the properties of the fibrinogen molecule, such as the conversion rate to fibrin and/or the characteristics of the fibrin clot. Also, genetic polymorphisms are known that can affect the function of the fibrinogen molecule. In addition, some other genetic variants are associated with plasma levels of fibrinogen and with the increase of fibrinogen levels during an acute-phase reaction. SUMMARY: In this review the authors discuss the noninherited and inherited variations of fibrinogen and the clinical implications (e.g. when determining the risk of cardiovascular disease).     

Fibrinogen and Fibrin Clot Structure in Diabetes

Diabetes is associated with an increased risk of developing cardiovascular disease, which is not fully accounted for by the accumulation of classic cardiovascular risk factors in patients. Recent evidence has demonstrated fibrinogen to be a powerful independent risk marker for cardiovascular disease in the general population, and it is also likely to contribute toward the increased atherosclerotic risk in diabetes. The etiology of hyperfibrinogenemia in diabetes is likely to be multifactorial, and at present the mechanisms involved have not been clarified. However, insulin, insulin resistance and inflammation are likely to be involved, especially in type 2 diabetes. The influence of diabetes in determining an individual's atherothrombotic risk is likely to extend beyond that of elevated fibrinogen levels, and may also act via changes in the structure and function of the fibrin clot that forms. Further research is needed to determine the mechanisms underlying these changes, which may lead to development of future interventions to reduce the excessive vascular risk associated with this disease.     

Role of platelets and antiplatelet therapy in cardiovascular disease

Platelets have a key role in normal hemostasis and in the pathogenesis of atherothrombotic events, such as acute coronary syndrome. Following plaque rupture, platelets adhere to the subendothelial matrix, become activated and then aggregate to form a prothrombotic surface that promotes clot formation and subsequently vascular occlusion. Multiple pathways are involved in platelet activation, including those activated by adenosine diphosphate (ADP), thromboxane A2, epinephrine, serotonin, collagen, and thrombin. Currently, two groups of inhibitors of platelet activation are approved for clinical use in patients with acute coronary syndromes: cyclooxygenase-1 inhibitors, namely aspirin, and oral ADP receptor antagonists such as clopidogrel. These agents have shown improved short- and long-term clinical outcomes but are associated with increased bleeding risk, and the rates of recurrent ischemic events remain high. These considerations underscore the need for novel antiplatelet agents that can provide greater reduction in recurrent atherothrombotic events without increasing the risk of bleeding. Several novel antiplatelet agents are currently under clinical development, such as more potent ADP receptor antagonists and protease-activated receptor-1 antagonists. This article provides an overview of the basic principles of platelet biology and the current status of knowledge on available oral antiplatelet therapy, as well as those under clinical development.     

Association between venous and arterial thrombosis: clinical implications

Venous and arterial thromboses have traditionally been regarded as separate diseases with different causes. However, recent epidemiological studies have documented an association between these vascular complications, probably due to the presence of more overlapping risk factors than previously recognized. This narrative review first focuses on the risk factors associated with both arterial and venous thrombotic events. In addition, it summarizes the more recent data on the risk of incident venous thromboembolism in patients with asymptomatic atherosclerosis or clinical manifestations of atherothrombosis, as well as on the risk of incident atherothrombotic events in patients with previous manifestation of venous thromboembolism. The potential clinical implications are also discussed.     

Genetics of fibrin clot structure: a twin study

Coronary artery thrombosis following plaque rupture is an important feature of myocardial infarction, and studies have highlighted the role of coagulation in this condition. Although genetic and environmental influences on the variance in coagulation protein concentrations have been reported, there are no data on the heritability of structure/function of the final phenotype of the coagulation cascade, the fibrin clot. To assess genetic and environmental contributions to fibrin structure, permeation and turbidity studies were performed in 137 twin pairs (66 monozygotic, 71 dizygotic). The environmental influence (e2) on pore size (Ks) (e2 = 0.61 [95% confidence interval (CI), 0.45-0.80]) and fiber size (e2 = 0.54 [95% CI, 0.39-0.73]) was greater than the heritability (h2 = 0.39 [95% CI, 0.20-0.55] and 0.46 [95% CI, 0.27-0.62], respectively). After correction for fibrinogen levels, the environmental effect persisted for Ks (e2 = 0.61), but genetic influence assumed a greater importance in determining fiber size (h2 = 0.73). Multivariate analysis revealed an overlap in the influence of genetic and environmental factors on fibrinogen levels, Ks, and fiber size. Factor XIII B subunit showed environmental and genetic correlation with fibrinogen and fiber size and a genetic correlation with Ks. The results indicate that genetic and environmental influences are important in determining fibrin clot structure/function.     

Acquired dysfibrinogenemia in atherosclerotic vascular disease

Acquired qualitative abnormalities of fibrinogen molecules, termed acquired dysfibrinogenemia, have been demonstrated in several disease states mostly related to prothrombotic tendency, including multiple myeloma and liver disease. Fibrin is abundant in atherosclerotic plaques. Altered plasma fibrin properties, reflected usually by reduced clot permeability and impaired fibrinolysis, have been reported in patients with acute or prior myocardial infarction, ischemic stroke, and peripheral artery disease. Moreover, prothrombotic clot phenotype has been observed in patients with previous no-reflow phenomenon and stent thrombosis. Growing evidence indicates that acquired dysfibrinogenemia contributes to the progression of atherosclerotic vascular disease and the occurrence of its thrombotic manifestations. The review summarizes current knowledge on the links between fibrin clot phenotype and atherosclerotic vascular disease and describes a wide spectrum of cardiovascular risk factors as modifiers of fibrin network characteristics.     

Diabetes mellitus as a prothrombotic condition

Diabetes mellitus (DM) is characterized by fasting hyperglycaemia and a high risk of atherothrombotic disorders affecting the coronary, cerebral and peripheral arterial trees. The risk of myocardial infarction (MI) is 3-5 fold higher in Type 2 DM and a DM subject with no history of MI has the same risk as a non-DM subject with a past history of MI. In total around 70% of deaths are vascular with poorer outcomes to both acute events and cardiological interventions. It was proposed that clustering of vascular risk factors (hyperinsulinaemia, dysglycaemia, dyslipidaemia and hypertension) around insulin resistance (IR) accounted for the increase in risk with Type 2 DM. The importance of this became apparent with the recognition that risk clustering occurs in normoglycaemic and impaired glucose tolerance (IGT) subjects with IR, in total around 25% of the population in addition to long-standing Type 1 subjects with renal disease. Evidence indicates that thrombotic risk clustering also occurs in association with IR, suppression of fibrinolysis due to elevated concentrations of the fibrinolytic inhibitor, plasminogen activator inhibitor-1 (PAI-1) is invariable with IR and there is evidence that this is regulated by the effects of triglyceride on the PAI-1 gene promoter. Other studies indicated that prothrombotic risk (coagulation factors VII, XII and fibrinogen) also associates with the IR syndrome. The development of endothelial cell dysfunction with suppression of nitric oxide and prostacyclin synthesis, combined with platelet resistance to the anti-aggregatory effects of these hormones leads to loss of control over platelet activation. In addition, hyperglycaemia and glycation have marked effects on fibrin structure function, generating a clot which has a denser structure, resistant to fibrinolysis. The combination of increased circulating coagulation zymogens, inhibition of fibrinolysis, changes in fibrin structure/function and alterations in platelet reactivity creates a thrombotic risk clustering which underpins the development of cardiovascular disease.     

Thrombin generation and fibrin clot structure

Generation of a hemostatic clot requires thrombin-mediated conversion of fibrinogen to fibrin. Previous in vitro studies have demonstrated that the thrombin concentration present at the time of gelation profoundly influences fibrin clot structure. Clots formed in the presence of low thrombin concentrations are composed of thick fibrin fibers and are highly susceptible to fibrinolysis; while, clots formed in the presence of high thrombin concentrations are composed of thin fibers and are relatively resistant to fibrinolysis. While most studies of clot formation have been performed by adding a fixed amount of purified thrombin to fibrinogen, clot formation in vivo occurs in a context of continuous, dynamic changes in thrombin concentration. These changes depend on the local concentrations of pro- and anti-coagulants and cellular activities. Recent studies suggest that patterns of abnormal thrombin generation produce clots with altered fibrin structure and that these changes are associated with an increased risk of bleeding or thrombosis. Furthermore, it is likely that clot structure also contributes to cellular events during wound healing. These findings suggest that studies explicitly evaluating fibrin formation during in situ thrombin generation are warranted to explain and fully appreciate mechanisms of normal and abnormal fibrin clot formation in vivo.     

Antiplatelet therapy for atherothrombotic disease: How can we improve the outcomes?

Platelets play a key role in hemostasis but are also responsible for the formation of pathogenic thrombi underlying the acute clinical manifestations of vascular atherothrombotic disease. Platelets are activated by multiple pathways, including adenosine diphosphate (ADP), thromboxane A₂ (TXA₂), and thrombin, ultimately leading to formation of platelet-rich thrombi that occlude the arterial lumen, resulting in ischemia and cardiovascular events. Current oral antiplatelet agents inhibit the TXA₂ (aspirin [ASA]) and ADP platelet activation pathways (P2Y₁₂ ADP receptor antagonists) and have demonstrated clinical efficacy for the reduction of morbidity and mortality in patients with atherothrombotic disease. However, these agents are associated with residual risk for thrombotic events, bleeding risk, and variability in response. Thus, there is a strong clinical need for novel antiplatelet therapies that decrease the risk of thrombotic events without exposing patients to increased risk of bleeding. This review describes the clinical safety and efficacy of ASA and P2Y₁₂ ADP receptor antagonists, the limitations of current antiplatelet therapy, and novel therapies in development, including newer P2Y₁₂ ADP receptor antagonists and protease-activated receptor (PAR-1) inhibitors.     

Biochemical and physiologic principles of tissue-type plasminogen activator

After wound healing the protective fibrin clot is removed by the fibrinolytic system. In addition fibrinolysis is one of the most important counter-reactions of blood coagulation. Fibrinolysis is controlled by activation and inhibition processes. Tissue type plasminogen activator (t-PA) and Pro-urokinase (single chain urokinase; scu-PA) hold a key position in physiological plasminogen activation. Plasmin itself is a rather unspecific protease capable of degrading a great variety of proteins besides fibrin. In vivo however--except for certain pathological situations--the fibrinolytic process is restricted to its actual target the fibrin clot. This surprising situation in terms of structure function interrelation is physiologically managed by N-terminal modules in the protein structure of the essential factors providing fibrin affinity. Free plasmin will be immediately inactivated by alpha 2-antiplasmin. Therefore fibrin plays a central role as cofactor in the fibrinolytic system in determining initiation and localization of the fibrinolytic process. Because of the superior properties of t-PA and scu-PA with respect to fibrin specificity both activators must be regarded as the future thrombolytic agents for therapy.     

Can haemostatic factors predict atherothrombosis?

Thrombosis is “haemostasis in the wrong place”, and there is increasing evidence that haemostatic factors are associated with increased risk of atherothrombotic events. Increasing plasma levels of fibrinogen are associated with increased risks of coronary heart disease, stroke and peripheral arterial disease, and with vascular and nonvascular mortality. However, as with other markers of haemostasis (and of inflammation), their additional predictive value to conventional risk factors is small. Ongoing studies of activation markers of coagulation (e.g. fibrin D-dimer), endothelium (e.g. von Willebrand factor, tissue plasminogen activator antigen) and platelets (mean platelet volume) may provide additional predictive value for atherothrombotic events. However, at present there is no sufficient evidence base for their routine measurement in prediction.     

Factor XIIa regulates the structure of the fibrin clot independently of thrombin generation through direct interaction with fibrin

Recent data indicate an important contribution of coagulation factor (F)XII to in vivo thrombus formation. Because fibrin structure plays a key role in clot stability and thrombosis, we hypothesized that FXII(a) interacts with fibrin(ogen) and thereby regulates clot structure and function. In plasma and purified system, we observed a dose-dependent increase in fibrin fiber density and decrease in turbidity, reflecting a denser structure, and a nonlinear increase in clot stiffness with FXIIa. In plasma, this increase was partly independent of thrombin generation, as shown in clots made in prothrombin-deficient plasma initiated with snake venom enzyme and in clots made from plasma deficient in FXII and prothrombin. Purified FXII and α-FXIIa, but not β-FXIIa, bound to purified fibrinogen and fibrin with nanomolar affinity. Immunostaining of human carotid artery thrombi showed that FXII colocalized with areas of dense fibrin deposition, providing evidence for the in vivo modulation of fibrin structure by FXIIa. These data demonstrate that FXIIa modulates fibrin clot structure independently of thrombin generation through direct binding of the N-terminus of FXIIa to fibrin(ogen). Modification of fibrin structure by FXIIa represents a novel physiologic role for the contact pathway that may contribute to the pathophysiology of thrombosis.     

Cardiovascular disease and heritability of the prothrombotic state

Atherothrombotic disease remains a major cause of mortality worldwide, and family clustering suggests an important contribution of genetic factors to disease pathogenesis. Thrombus formation represents the final step in atherothrombosis, a process influenced by genetic and environmental factors. A major difficulty of investigating the genetic regulation of thrombotic conditions is the complexity of the phenotype and the relatively modest effects of individual genetic variations. We address in this review genetic aspects involved in regulating thrombosis potential and their impact on the development of atherothrombotic disease. The effects of common genetic polymorphisms in clotting factors are discussed and examples of complex gene-gene and gene-environment interactions are highlighted. Understanding the effects of genetic factors on predisposition to thrombotic disease and unravelling the complex gene-environment interactions will help to better understand the pathophysiology of this complex condition, which will enable the development of new preventative and treatment strategies.     

Fibrin clot formation and lysis: basic mechanisms

The hemostatic balance, introduced more than 40 years ago, addresses the components and reactions involved in fibrin turnover. Fibrin is placed in the core of this delicate balance. Defects in the mechanisms responsible for fibrin turnover might lead to thrombosis or bleeding, and fibrin consequently is an important substrate in the physiology of hemostasis. This review describes the components and processes involved in fibrin formation and fibrin degradation. Particular emphasis is put on the reactions involved in the conversion of fibrinogen to fibrin, the polymerization of fibrin molecules induced by coagulation factor XIII (FXIII), and the degradation of fibrinogen and fibrin mediated by plasmin and elastase. Furthermore, factors influencing fibrin structure and fibrin breakdown are addressed; in particular polymorphisms in the genes coding for fibrinogen and FXIII, but also the physical and biochemical conditions in which fibrin is formed. The past decades have produced a bulk of biochemical publications reviewing fibrin turnover and fibrin structure, and it has been shown that alterations in fibrin structure are important for the development of various disease conditions, whereas, the architecture of fibrin can be modified by certain drugs and chemical compounds. However, these topics deserve increased attention in clinical settings. Of particular importance might be more detailed clinical studies that review the influence of polymorphisms in the genes coding for the key factors involved in fibrin metabolism on the development of hemostatic diseases, but also the role of elastase-induced fibrin degradation deserves increased attention.     

Plasminogen activator inhibitor 1, fibrin, and the vascular response to injury

Intravascular fibrin deposition is believed to play an important role in the development of intimal hyperplasia, which is a hallmark of several human vascular disorders, including atherosclerosis and restenosis after balloon angioplasty. Plasminogen activator inhibitor-1 (PAI-1), the primary inhibitor or tissue- and urinary-type plasminogen activator, plays a key role in fibrin homeostasis by controlling plasmin formation. PAI-1 may also modulate vascular pathology via alternative pathways, such as inhibiting activated protein C and altering interactions between vascular smooth muscle cells and the extracellular matrix. The diverse functional profile of PAI-1 likely accounts for the variation observed in its impact on intimal hyperplasia in different disease models. This review examines recent studies addressing the vascular function of PAI-1, and those assessing the role of fibrin as a downstream mediator of PAI-1's effects.     

Calpain regulation of integrin alpha IIb beta 3 signaling in human platelets

Efficient platelet adhesion and aggregation at sites of vascular injury requires the synergistic contribution of multiple adhesion receptors. The initial adhesion of platelets to subendothelial matrix proteins involves GPIb/V/IX and one or more platelet integrins, including integrin alpha IIb beta 3, alpha 2 beta 1, alpha 5 beta 1 and possibly alpha 6 beta 1. In contrast, platelet-platelet adhesion (platelet cohesion or aggregation) is mediated exclusively by GPIb/V/IX and integrin alpha IIb beta 3. Integrin alpha IIb beta 3 is a remarkable receptor that not only stabilizes platelet-vessel wall and platelet-platelet adhesion contacts, but also transduces signals necessary for a range of other functional responses. These signals are linked to cytoskeletal reorganization and platelet spreading, membrane vesiculation and fibrin clot formation, and tension development on a fibrin clot leading to clot retraction. This diverse functional role of integrin alpha IIb beta 3 is reflected by its ability to induce the activation of a broad range of signaling enzymes that are involved in membrane phospholipid metabolism, protein phosphorylation, calcium mobilization and activation of small GTPases. An important calcium-dependent signaling enzyme involved in integrin alpha IIb beta 3 outside-in signaling is the thiol protease, calpain. This enzyme proteolyses a number of key structural and signaling proteins involved in cytoskeletal remodeling and platelet activation. These proteolytic events appear to play a potentially important role in modulating the adhesive and signaling function of integrin alpha IIb beta 3.